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A Velocity Measurement Method Based on Scaling Parameter Estimation of a Chaotic System

Lidong Liu Jifeng Hu Zishu He Chunlin Han Huiyong Li Jun Li
Metrology and Measurement Systems | 2011 | No 2 | 275-282 | DOI: 10.2478/v10178-011-0009-1
Keywords signal processing parameter estimation chaos synchronization
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Abstract

In this paper, we propose a new method of measuring the target velocity by estimating the scaling parameter of a chaos-generating system. First, we derive the relation between the target velocity and the scaling parameter of the chaos-generating system. Then a new method for scaling parameter estimation of the chaotic system is proposed by exploiting the chaotic synchronization property. Finally, numerical simulations show the effectiveness of the proposed method in target velocity measurement.

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Authors and Affiliations

Lidong Liu
Jifeng Hu
Zishu He
Chunlin Han
Huiyong Li
Jun Li

Review of Lattice Boltzmann Method Applied to Computational Aeroacoustics

Weidong Shao Jun Li
Archives of Acoustics | 2019 | vol. 44 | No 2 | 215-238 | DOI: 10.24425/aoa.2019.128486
Keywords lattice Boltzmann method computational aeroacoustics dispersion and dissipation perfectly matched layers discontinuous Galerkin method
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Abstract

This paper presents the research studies carried out on the application of lattice Boltzmann method (LBM) to computational aeroacoustics (CAA). The Navier-Stokes equation-based solver faces the difficulty of computational efficiency when it has to satisfy the high-order of accuracy and spectral resolution. LBM shows its capabilities in direct and indirect noise computations with superior space-time resolution. The combination of LBM with turbulence models also work very well for practical engineering machinery noise. The hybrid LBM decouples the discretization of physical space from the discretization of moment space, resulting in flexible mesh and adjustable time-marching. Moreover, new solving strategies and acoustic models are developed to further promote the application of LBM to CAA.

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Authors and Affiliations

Weidong Shao
Jun Li

Short-term wind power combined prediction based on EWT-SMMKL methods

Jun Li Liancai Ma
Archives of Electrical Engineering | 2021 | vol. 70 | No 4 | 801-817 | DOI: 10.24425/aee.2021.138262
Keywords combined model empirical wavelet transform prediction soft margin multiple kernel learning wind power
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Abstract

Since wind power generation has strong randomness and is difficult to predict, a class of combined prediction methods based on empiricalwavelet transform(EWT) and soft margin multiple kernel learning (SMMKL) is proposed in this paper. As a new approach to build adaptive wavelets, the main idea is to extract the different modes of signals by designing an appropriate wavelet filter bank. The SMMKL method effectively avoids the disadvantage of the hard margin MKL method of selecting only a few base kernels and discarding other useful basis kernels when solving for the objective function. Firstly, the EWT method is used to decompose the time series data. Secondly, different SMMKL forecasting models are constructed for the sub-sequences formed by each mode component signal. The training processes of the forecasting model are respectively implemented by two different methods, i.e., the hinge loss soft margin MKL and the square hinge loss soft margin MKL. Simultaneously, the ultimate forecasting results can be obtained by the superposition of the corresponding forecasting model. In order to verify the effectiveness of the proposed method, it was applied to an actual wind speed data set from National Renewable Energy Laboratory (NREL) for short-term wind power single-step or multi-step time series indirectly forecasting. Compared with a radial basic function (RBF) kernelbased support vector machine (SVM), using SimpleMKL under the same condition, the experimental results show that the proposed EWT-SMMKL methods based on two different algorithms have higher forecasting accuracy, and the combined models show effectiveness.
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Bibliography

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Authors and Affiliations

Jun Li
1
Liancai Ma
1
  1. Lanzhou Jiaotong University, Lanzhou, Gansu 730070, China

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